Overmolded Or Pressed-In Sleeve For Hydraulic Routing Of Solenoid

ABSTRACT

A valve having a metal insert with a fluid passage formed in the metal insert. A composite valve body is disposed at least partially around the metal insert and having at least one port in fluid communication) with the fluid passage with the metal insert. A valve member is partially disposed in the metal insert and operable to control the fluid flow through the fluid passage of the metal insert and parts of the valve body.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 14/268,047 filed on May 2, 2014, which is a continuation of U.S. patent application Ser. No. 12/988,811 filed on Dec. 20, 2010, now U.S. Pat. No. 8,757,209 issued on Jun. 24, 2014, which is the National Stage of International Application No. PCT/US2009/039287 filed on Apr. 2, 2009, which claims priority to U.S. Provisional Patent Application No. 61/125,703 filed on Apr. 28, 2008. The disclosures of the above applications are herein incorporated by reference in their entirety.

FIELD OF THE INVENTION

The present invention relates to overmolded solenoid valve bodies, and more specially solenoid valves having metal sleeves pressed in or overmolded to a composite valve body.

BACKGROUND OF THE INVENTION

Solenoid valves for automotive components have become common place in the industry. The solenoid valves are used to control various hydraulic components such as transmission, clutch, turbocharger, drive line components, and exhaust control components. Typically, solenoid valves have a valve body that is actuated by a solenoid portion which consists of an electromagnetic coil having an armature that moves in response to the application of current to the electromagnetic portion. In the past the valve bodies have been made out of machined metal components. The flow path through the valve body has been defined by forming holes and bores in the metal valve body. The trend in solenoid designs has been to increase their ability through the use of more complex flow paths through the valve body itself. Thus, there is an increased need for more comprehensive fluid passages in the valve body in order to make the solenoid valve more versatile and keep up with the performance demands that exist in the industry. Additionally, suppliers have an interest in being able to manufacture solenoid valves in a more cost effective manner to be able to offer the marketplace a lower cost, higher performance product.

SUMMARY OF THE INVENTION

The present invention relates to a valve having a metal insert with a fluid passage formed in the metal insert. A composite valve body is disposed at least partially around the metal insert and having at least one port in fluid communication with the fluid passage of the metal insert. A valve member is partially disposed in the metal insert and operable to control the fluid flow through the fluid passage of the metal insert and parts of the valve body.

Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:

FIG. 1 is a cross-sectional plan view of a prior art valve portion;

FIG. 2 is a cross-sectional plan view in accordance with a present embodiment of the invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.

Referring now to FIG. 1, a prior art solenoid valve assembly 10 is shown. The valve assembly 10 has a metal valve body 12 having machined ports 14 which are typically formed in the metal valve body 12 by boring or milling through the metal valve body 12. The machined ports 14 extend into a machined bore 15 which is also formed in the metal valve body 12. A valve member 16 is slideably positioned within the machined bore 15 of the metal valve body 12. The valve member 16 has a fluid passage 18 that is used to communicate fluid between the machined ports.

FIG. 2 is a cross-sectional view of a composite pressure control solenoid valve assembly 100 in accordance with the present embodiment of the invention. The valve assembly 100 has a valve portion 102 and a solenoid actuator portion 104. The solenoid actuator portion 104 and valve portion 102 can be separate or integrated and be made from the same material. The valve portion 102 has a composite valve body 110 that is made of a composite material which is molded from composite resin. The composite material that makes up the composite body 110 would be any type of suitable plastic material. More specifically, thermal plastics such as polyamids, including nylon, polyphthalamides, and liquid crystal polymers. However, the principle materials used are not necessarily limited to these particular materials, other plastic materials may be more suitable for a particular application.

The composite valve body 110 has one or more ports molded therein. In this particular embodiment, the one or more ports include a supply port 114, control port 116, and exhaust port 118. Each of the ports 114, 116, 118 extend to a bore of the composite valve body 110. The bore of the valve body 113 is formed through the molding process or processes described below. Additionally, the greater of lesser numbers of ports can be implemented based on the design of a particular application.

Within the bore 113 of the composite valve body 110 is a metal insert 106. A fluid passage 108 with several apertures 109 that extend from the exterior of the metal insert 106 to the fluid passage 108 are formed in the metal insert 106. The fluid passage 108 is formed by machining the metal insert 106. The metal insert 106 is positioned in the bore 113 of the composite valve body 110. The metal insert 106 can be placed within the bore 113 of the composite valve body 110 by overmolding the composite valve body 110 around the metal insert 106. Another process involves press fitting the metal insert 106 into the already formed valve body 110.

The apertures 109 of the metal insert 106 are configured to align with one or more of the ports 114, 116, 118 of the composite valve body 110. This allows for fluid communication from outside of the composite valve body 110 to flow into the fluid passage 108 of the metal insert 106.

A spool valve member 112 is slideably positioned within the metal insert 106 and has a fluid passage 119 formed therein. The fluid passage 119 in this particular embodiment communicates with the control port 116 and the supply port 114 and exhaust port 118 through metering orifices 126. The metal insert 106 has upper and lower bearings 140, 142 aligning the spool valve 112. The metal insert 106 has metering lands 128 formed in the fluid passage 108 of the metal insert 106. The metering lands 128 align with the metering orifices 126 and function to control the flow of fluid through the metering orifices 126 when the valve member 112 is placed in a position where the metering orifices 126 are aligned with the metering lands 128. The metering lands 128 have metering edges 130 that permit the flow of fluid through the metering orifices 126 when the valve member 112 is moved axially within the fluid passage 108 of the metal insert 106.

The valve assembly 100 of the present embodiment significantly reduces the production cost and manufacturing time when compared to the prior art valve of FIG. 1. The composite valve body 110 is less expensive and easier to form than the metal valve body 12. The metal insert 106 and the valve member 112 are the only components that have to be machined. These components are smaller and present less metal that has to be machined. Additionally, the valve member 112 and metal inset 106 can be preassembled and checked for quality prior to being placed in the composite valve body 110. This also saves time and even allows the metal insert 106 and valve member 112 to be manufactured separately which also presents cost savings.

The valve assembly 100 has an actuator portion 104 which in the present embodiment of the invention is a solenoid portion. The actuator portion has a housing 105 that can be a separate component; however, in this particular embodiment of the invention the housing 105 is a composite housing that is integral with the composite valve body 100 of the valve portion 102. Within the actuator portion 104 is a coil 120 that when energized causes an armature 122 to move axially. A pin 123 is connected to the armature 122 and contacts the valve member 112 of the valve portion 102 in order to cause the valve member 112 to move axially within the metal insert 106. A spring 121 is operably connected to the pin 123 for biasing the armature in one direction when the coil 120 is not energized.

The present invention provides a composite valve body 110 that is formed by molding composite resins. This lowers the over all cost of production and also provides the advantage of being able to form more complex fluid passages within the composite valve body 110 while eliminating the machining step that would normally be required for a metal valve body 12 as shown in FIG. 1. Furthermore, there are fluid passages that can be molded into the composite valve body 110 that could not be easily formed in a traditional metal valve body 12.

The present invention also includes a method of making a composite solenoid valve or valve assembly 100 as shown in FIG. 2. The method of making the valve assembly 100 includes providing the metal insert 106, composite valve body 110, valve member 112, fluid passage 119 of valve member 112, and at least one port 114, 116, 118 in the composite valve body 110 and apertures 109 in the metal insert 106. The step of forming the fluid passage 119 in the metal insert 106 is carried out by machining or drilling the fluid passage from metal stock.

The valve member 112 also has fluid passages 119 and apertures 126 machined or formed by machining and boring the passages out of the valve member 112. While the present invention describes a valve member 112 that is formed of metal it is within the scope of this invention to have the valve member 112 also formed from composite material whereby the fluid passages and apertures are formed through a molding process. The valve member 112 has been placed in the fluid passage 108 of the metal insert 106.

The valve member 112 is then placed in a slidable arrangement within the fluid passage 108 of the metal insert 106. The metal insert 106 is then connected to the composite valve body 110. This process can be carried out in several different ways. One process is to press fit the metal insert 106 into an already formed composite valve body 110. Another step involves placing the metal insert 106 into a mold and then overmolding the composite valve body 110 around the metal insert 106. The supply port 114, control port 116, and exhaust port 118 are formed in the composite valve body 110 either through the overmolding process or by drilling the ports through the formed composite valve body 110. The metal insert 106 may have a stepped or mold feature on its exterior surface such that in order to more tightly secure the metal insert 106 to the valve body 110. Such features will eliminate any possible leaking that can occur between the plastic and the metal and also to insure retention of the metal insert.

If the actuator portion 104 is separate from the valve portion 102 then the actuator is connected to the composite valve body 110. Alternatively, the casing 105 of the actuator portion 104 can be overmolded in the same or separate step as the metal insert 106 is overmolded with the composite valve body 110. Thus, the casing 105 of the actuator portion 104 can be integral with the composite valve body 110.

The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention. 

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 7. A solenoid pressure control valve comprising: a metal insert having a fluid passage formed in said metal insert; a composite valve body disposed at least partially around said metal insert, wherein said composite valve body has a bore where said metal insert is positioned; a supply port disposed through said composite valve body and said metal insert, wherein said supply port is connected to said fluid passage; a control port disposed through said composite valve body and said metal insert, wherein said control port is connected to said fluid passage; a valve member at least partially disposed in said metal insert for controlling the flow of fluid medium between said supply port and said control port by moving with respect to said metal insert; and a solenoid portion having a coil with an armature moveable within said solenoid portion in response to energization of said coil, wherein said armature causes said valve member to slide within said fluid passage.
 8. (canceled)
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 11. (canceled)
 12. The solenoid pressure control valve of claim 7, wherein said composite valve body is composed of a thermoplastics material.
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 18. The solenoid pressure control valve of claim 7, further comprising a metering land formed in said fluid passage for controlling the flow of fluid medium through said fluid passage.
 19. The solenoid pressure control valve of claim 7, further comprising a metering orifice for fluidly communicating said fluid passage with at least one of said control port and said supply port.
 20. The solenoid pressure control valve of claim 19, further comprising a metering land, with said metering land engageable with said metering orifice for controlling the flow of fluid medium through said metering orifice.
 21. The solenoid pressure control valve of claim 20, wherein said metering land has metering edges for metering the flow of fluid medium through said metering orifice.
 22. The solenoid pressure control valve of claim 20, wherein said metal insert presents said metering land.
 23. The solenoid pressure control valve of claim 7, wherein said composite valve body is overmolded at least partially around said metal insert.
 24. The solenoid pressure control valve of claim 7, wherein said valve member has a bore extending at least partially through said valve member for providing the flow of fluid medium between said supply port and said control port.
 25. The solenoid pressure control valve of claim 24, further comprising a metering orifice for fluidly communicating said fluid passage with at least one of said control port and said supply port, wherein said metering orifice extends through said valve member between said bore and said fluid passage.
 26. The solenoid pressure control valve of claim 7, wherein said valve member is further defined as a spool valve member.
 27. The solenoid pressure control valve of claim 7, wherein said metal insert has upper and lower bearings.
 28. A solenoid pressure control valve comprising: a metal insert having a fluid passage formed in said metal insert; a composite valve body disposed at least partially around said metal insert, wherein said composite valve body has a bore where said metal insert is positioned; a supply port disposed through said composite valve body and said metal insert, wherein said supply port is connected to said fluid passage; a control port disposed through said composite valve body and said metal insert, wherein said control port is connected to said fluid passage; a valve member at least partially disposed in said metal insert for controlling the flow of fluid medium between said supply port and said control port with respect to said metal insert; and a solenoid portion having a coil with an armature moveable within said solenoid portion in response to energization of said coil, wherein said armature causes said valve member to slide within said fluid passage; wherein one of said metal insert and said valve member presents a metering land for controlling the flow of fluid medium through said fluid passage, and the other one of said metal insert and said valve member defines a metering orifice for fluidly communicating said fluid passage with at least one of said control port and said supply port.
 29. The solenoid pressure control valve of claim 28, wherein said composite valve body is composed of a thermoplastics material.
 30. The solenoid pressure control valve of claim 28, wherein said metering land is engageable with said metering orifice for controlling the flow of fluid medium through said metering orifice.
 31. The solenoid pressure control valve of claim 28, wherein said metering land has metering edges for metering the flow of fluid medium through said metering orifice.
 32. The solenoid pressure control valve of claim 28, wherein said metal insert presents said metering land.
 33. The solenoid pressure control valve of claim 28, wherein said composite valve body is overmolded at least partially around said metal insert.
 34. The solenoid pressure control valve of claim 28, wherein said valve member has a bore extending at least partially through said valve member for providing the flow of fluid medium between said supply port and said control port.
 35. The solenoid pressure control valve of claim 34, wherein said metering orifice extends through said valve member between said bore and said fluid passage.
 36. The solenoid pressure control valve of claim 28, wherein said metal insert has upper and lower bearings.
 37. The solenoid pressure control valve of claim 28, wherein said valve member is further defined as a spool valve member. 